An extended energy balance method for resonance prediction in forced response of systems with non-conservative nonlinearities using damped nonlinear normal mode
An extended energy balance method for resonance prediction in forced response of systems with non-conservative nonlinearities using damped nonlinear normal mode
The dynamic analysis of systems with nonlinearities has become an important topic in many engineering fields. Apart from the forced response analyses, nonlinear modal analysis has been successfully extended to such non-conservative systems thanks to the definition of damped nonlinear normal modes. The energy balance method is a tool that permits to directly predict resonances for a conservative system with nonlinearities from its nonlinear modes. In this work, the energy balance method is extended to systems with non-conservative nonlinearities using the concept of the damped nonlinear normal mode and its application in a full-scale engineering structure. This extended method consists of a balance between the energy loss from the internal damping, the energy transferred from the external excitation and the energy exchanged with the non-conservative nonlinear force. The method assumes that the solution of the forced response at resonance bears resemblance to that of the damped nonlinear normal mode. A simplistic model and full-scale structure with dissipative nonlinearities and a simplistic model showing self-excited vibration are tested using the method. In each test case, resonances are predicted efficiently and the computed force–amplitude curves show a great agreement with the forced responses. In addition, the self-excited solutions and isolas in forced responses can be effectively detected and identified. The accuracy and limitations of the method have been critically discussed in this work.
3315–3333
Sun, Y.
7d536759-a700-4839-8511-5378746ba8a9
Vizzaccaro, A.
7318a706-c481-49ce-a1b2-9e26a749605d
Yuan, J.
4bcf9ce8-3af4-4009-9cd0-067521894797
Salles, L.
1b179daa-7bb9-4f34-8b5f-dfc05b496969
10 July 2020
Sun, Y.
7d536759-a700-4839-8511-5378746ba8a9
Vizzaccaro, A.
7318a706-c481-49ce-a1b2-9e26a749605d
Yuan, J.
4bcf9ce8-3af4-4009-9cd0-067521894797
Salles, L.
1b179daa-7bb9-4f34-8b5f-dfc05b496969
Sun, Y., Vizzaccaro, A., Yuan, J. and Salles, L.
(2020)
An extended energy balance method for resonance prediction in forced response of systems with non-conservative nonlinearities using damped nonlinear normal mode.
Nonlinear Dynamics, 103, .
(doi:10.1007/s11071-020-05793-2).
Abstract
The dynamic analysis of systems with nonlinearities has become an important topic in many engineering fields. Apart from the forced response analyses, nonlinear modal analysis has been successfully extended to such non-conservative systems thanks to the definition of damped nonlinear normal modes. The energy balance method is a tool that permits to directly predict resonances for a conservative system with nonlinearities from its nonlinear modes. In this work, the energy balance method is extended to systems with non-conservative nonlinearities using the concept of the damped nonlinear normal mode and its application in a full-scale engineering structure. This extended method consists of a balance between the energy loss from the internal damping, the energy transferred from the external excitation and the energy exchanged with the non-conservative nonlinear force. The method assumes that the solution of the forced response at resonance bears resemblance to that of the damped nonlinear normal mode. A simplistic model and full-scale structure with dissipative nonlinearities and a simplistic model showing self-excited vibration are tested using the method. In each test case, resonances are predicted efficiently and the computed force–amplitude curves show a great agreement with the forced responses. In addition, the self-excited solutions and isolas in forced responses can be effectively detected and identified. The accuracy and limitations of the method have been critically discussed in this work.
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s11071-020-05793-2
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Accepted/In Press date: 10 June 2020
Published date: 10 July 2020
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Local EPrints ID: 478901
URI: http://eprints.soton.ac.uk/id/eprint/478901
ISSN: 0924-090X
PURE UUID: e8ab5019-25b0-4676-bf8e-bd60dc1e821a
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Date deposited: 12 Jul 2023 16:46
Last modified: 17 Mar 2024 04:20
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Author:
Y. Sun
Author:
A. Vizzaccaro
Author:
J. Yuan
Author:
L. Salles
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